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path: root/src/mem/protocol/MESI_Three_Level-L0cache.sm
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/*
 * Copyright (c) 2013 Mark D. Hill and David A. Wood
 * All rights reserved.
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions are
 * met: redistributions of source code must retain the above copyright
 * notice, this list of conditions and the following disclaimer;
 * redistributions in binary form must reproduce the above copyright
 * notice, this list of conditions and the following disclaimer in the
 * documentation and/or other materials provided with the distribution;
 * neither the name of the copyright holders nor the names of its
 * contributors may be used to endorse or promote products derived from
 * this software without specific prior written permission.
 *
 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
 * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
 * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
 * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
 * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
 * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
 * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
 * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
 */

machine(L0Cache, "MESI Directory L0 Cache")
 : Sequencer * sequencer,
   CacheMemory * Icache,
   CacheMemory * Dcache,
   Cycles request_latency = 2,
   Cycles response_latency = 2,
   bool send_evictions,
{
  // NODE L0 CACHE
  // From this node's L0 cache to the network
  MessageBuffer bufferFromCache, network="To", physical_network="0", ordered="true";

  // To this node's L0 cache FROM the network
  MessageBuffer bufferToCache, network="From", physical_network="0", ordered="true";

  // Message queue between this controller and the processor
  MessageBuffer mandatoryQueue, ordered="false";

  // STATES
  state_declaration(State, desc="Cache states", default="L0Cache_State_I") {
    // Base states

    // The cache entry has not been allocated.
    NP, AccessPermission:Invalid, desc="Not present in either cache";

    // The cache entry has been allocated, but is not in use.
    I, AccessPermission:Invalid;

    // The cache entry is in shared mode. The processor can read this entry
    // but it cannot write to it.
    S, AccessPermission:Read_Only;

    // The cache entry is in exclusive mode. The processor can read this
    // entry. It can write to this entry without informing the directory.
    // On writing, the entry moves to M state.
    E, AccessPermission:Read_Only;

    // The processor has read and write permissions on this entry.
    M, AccessPermission:Read_Write;

    // Transient States

    // The cache controller has requested that this entry be fetched in
    // shared state so that the processor can read it.
    IS, AccessPermission:Busy;

    // The cache controller has requested that this entry be fetched in
    // modify state so that the processor can read/write it.
    IM, AccessPermission:Busy;

    // The cache controller had read permission over the entry. But now the
    // processor needs to write to it. So, the controller has requested for
    // write permission.
    SM, AccessPermission:Read_Only;
  }

  // EVENTS
  enumeration(Event, desc="Cache events") {
    // L0 events
    Load,            desc="Load request from the home processor";
    Ifetch,          desc="I-fetch request from the home processor";
    Store,           desc="Store request from the home processor";

    Inv,           desc="Invalidate request from L2 bank";

    // internal generated request
    L0_Replacement,  desc="L0 Replacement", format="!r";

    // other requests
    Fwd_GETX,   desc="GETX from other processor";
    Fwd_GETS,   desc="GETS from other processor";
    Fwd_GET_INSTR,   desc="GET_INSTR from other processor";

    Data,               desc="Data for processor";
    Data_Exclusive,     desc="Data for processor";
    Data_Stale,         desc="Data for processor, but not for storage";

    Ack,        desc="Ack for processor";
    Ack_all,      desc="Last ack for processor";

    WB_Ack,        desc="Ack for replacement";
  }

  // TYPES

  // CacheEntry
  structure(Entry, desc="...", interface="AbstractCacheEntry" ) {
    State CacheState,        desc="cache state";
    DataBlock DataBlk,       desc="data for the block";
    bool Dirty, default="false",   desc="data is dirty";
  }

  // TBE fields
  structure(TBE, desc="...") {
    Address Addr,              desc="Physical address for this TBE";
    State TBEState,        desc="Transient state";
    DataBlock DataBlk,                desc="Buffer for the data block";
    bool Dirty, default="false",   desc="data is dirty";
    int pendingAcks, default="0", desc="number of pending acks";
  }

  structure(TBETable, external="yes") {
    TBE lookup(Address);
    void allocate(Address);
    void deallocate(Address);
    bool isPresent(Address);
  }

  TBETable TBEs, template="<L0Cache_TBE>", constructor="m_number_of_TBEs";

  void set_cache_entry(AbstractCacheEntry a);
  void unset_cache_entry();
  void set_tbe(TBE a);
  void unset_tbe();
  void wakeUpBuffers(Address a);
  void wakeUpAllBuffers(Address a);
  void profileMsgDelay(int virtualNetworkType, Cycles c);

  // inclusive cache returns L0 entries only
  Entry getCacheEntry(Address addr), return_by_pointer="yes" {
    Entry Dcache_entry := static_cast(Entry, "pointer", Dcache[addr]);
    if(is_valid(Dcache_entry)) {
      return Dcache_entry;
    }

    Entry Icache_entry := static_cast(Entry, "pointer", Icache[addr]);
    return Icache_entry;
  }

  Entry getDCacheEntry(Address addr), return_by_pointer="yes" {
    Entry Dcache_entry := static_cast(Entry, "pointer", Dcache[addr]);
    return Dcache_entry;
  }

  Entry getICacheEntry(Address addr), return_by_pointer="yes" {
    Entry Icache_entry := static_cast(Entry, "pointer", Icache[addr]);
    return Icache_entry;
  }

  State getState(TBE tbe, Entry cache_entry, Address addr) {
    assert((Dcache.isTagPresent(addr) && Icache.isTagPresent(addr)) == false);

    if(is_valid(tbe)) {
      return tbe.TBEState;
    } else if (is_valid(cache_entry)) {
      return cache_entry.CacheState;
    }
    return State:NP;
  }

  void setState(TBE tbe, Entry cache_entry, Address addr, State state) {
    assert((Dcache.isTagPresent(addr) && Icache.isTagPresent(addr)) == false);

    // MUST CHANGE
    if(is_valid(tbe)) {
      tbe.TBEState := state;
    }

    if (is_valid(cache_entry)) {
      cache_entry.CacheState := state;
    }
  }

  AccessPermission getAccessPermission(Address addr) {
    TBE tbe := TBEs[addr];
    if(is_valid(tbe)) {
      DPRINTF(RubySlicc, "%s\n", L0Cache_State_to_permission(tbe.TBEState));
      return L0Cache_State_to_permission(tbe.TBEState);
    }

    Entry cache_entry := getCacheEntry(addr);
    if(is_valid(cache_entry)) {
      DPRINTF(RubySlicc, "%s\n", L0Cache_State_to_permission(cache_entry.CacheState));
      return L0Cache_State_to_permission(cache_entry.CacheState);
    }

    DPRINTF(RubySlicc, "%s\n", AccessPermission:NotPresent);
    return AccessPermission:NotPresent;
  }

  DataBlock getDataBlock(Address addr), return_by_ref="yes" {
    TBE tbe := TBEs[addr];
    if(is_valid(tbe)) {
        return tbe.DataBlk;
    }

    return getCacheEntry(addr).DataBlk;
  }

  void setAccessPermission(Entry cache_entry, Address addr, State state) {
    if (is_valid(cache_entry)) {
      cache_entry.changePermission(L0Cache_State_to_permission(state));
    }
  }

  Event mandatory_request_type_to_event(RubyRequestType type) {
    if (type == RubyRequestType:LD) {
      return Event:Load;
    } else if (type == RubyRequestType:IFETCH) {
      return Event:Ifetch;
    } else if ((type == RubyRequestType:ST) || (type == RubyRequestType:ATOMIC)) {
      return Event:Store;
    } else {
      error("Invalid RubyRequestType");
    }
  }

  int getPendingAcks(TBE tbe) {
    return tbe.pendingAcks;
  }

  out_port(requestNetwork_out, CoherenceMsg, bufferFromCache);

  // Messages for this L0 cache from the L1 cache
  in_port(messgeBuffer_in, CoherenceMsg, bufferToCache, rank = 1) {
    if (messgeBuffer_in.isReady()) {
      peek(messgeBuffer_in, CoherenceMsg, block_on="Addr") {
        assert(in_msg.Destination == machineID);

        Entry cache_entry := getCacheEntry(in_msg.Addr);
        TBE tbe := TBEs[in_msg.Addr];

        if(in_msg.Class == CoherenceClass:DATA_EXCLUSIVE) {
            trigger(Event:Data_Exclusive, in_msg.Addr, cache_entry, tbe);
        } else if(in_msg.Class == CoherenceClass:DATA) {
            trigger(Event:Data, in_msg.Addr, cache_entry, tbe);
        } else if(in_msg.Class == CoherenceClass:STALE_DATA) {
            trigger(Event:Data_Stale, in_msg.Addr, cache_entry, tbe);
        } else if (in_msg.Class == CoherenceClass:ACK) {
            trigger(Event:Ack, in_msg.Addr, cache_entry, tbe);
        } else if (in_msg.Class == CoherenceClass:WB_ACK) {
            trigger(Event:WB_Ack, in_msg.Addr, cache_entry, tbe);
        } else if (in_msg.Class == CoherenceClass:INV) {
          trigger(Event:Inv, in_msg.Addr, cache_entry, tbe);
        } else if (in_msg.Class == CoherenceClass:GETX ||
                   in_msg.Class == CoherenceClass:UPGRADE) {
          // upgrade transforms to GETX due to race
          trigger(Event:Fwd_GETX, in_msg.Addr, cache_entry, tbe);
        } else if (in_msg.Class == CoherenceClass:GETS) {
          trigger(Event:Fwd_GETS, in_msg.Addr, cache_entry, tbe);
        } else if (in_msg.Class == CoherenceClass:GET_INSTR) {
          trigger(Event:Fwd_GET_INSTR, in_msg.Addr, cache_entry, tbe);
        } else {
          error("Invalid forwarded request type");
        }
      }
    }
  }

  // Mandatory Queue betweens Node's CPU and it's L0 caches
  in_port(mandatoryQueue_in, RubyRequest, mandatoryQueue, desc="...", rank = 0) {
    if (mandatoryQueue_in.isReady()) {
      peek(mandatoryQueue_in, RubyRequest, block_on="LineAddress") {

        // Check for data access to blocks in I-cache and ifetchs to blocks in D-cache

        if (in_msg.Type == RubyRequestType:IFETCH) {
          // ** INSTRUCTION ACCESS ***

          Entry Icache_entry := getICacheEntry(in_msg.LineAddress);
          if (is_valid(Icache_entry)) {
            // The tag matches for the L0, so the L0 asks the L2 for it.
            trigger(mandatory_request_type_to_event(in_msg.Type), in_msg.LineAddress,
                    Icache_entry, TBEs[in_msg.LineAddress]);
          } else {

            // Check to see if it is in the OTHER L0
            Entry Dcache_entry := getDCacheEntry(in_msg.LineAddress);
            if (is_valid(Dcache_entry)) {
              // The block is in the wrong L0, put the request on the queue to the shared L2
              trigger(Event:L0_Replacement, in_msg.LineAddress,
                      Dcache_entry, TBEs[in_msg.LineAddress]);
            }

            if (Icache.cacheAvail(in_msg.LineAddress)) {
              // L0 does't have the line, but we have space for it
              // in the L0 so let's see if the L2 has it
              trigger(mandatory_request_type_to_event(in_msg.Type), in_msg.LineAddress,
                      Icache_entry, TBEs[in_msg.LineAddress]);
            } else {
              // No room in the L0, so we need to make room in the L0
              trigger(Event:L0_Replacement, Icache.cacheProbe(in_msg.LineAddress),
                      getICacheEntry(Icache.cacheProbe(in_msg.LineAddress)),
                      TBEs[Icache.cacheProbe(in_msg.LineAddress)]);
            }
          }
        } else {

          // *** DATA ACCESS ***
          Entry Dcache_entry := getDCacheEntry(in_msg.LineAddress);
          if (is_valid(Dcache_entry)) {
            // The tag matches for the L0, so the L0 ask the L1 for it
            trigger(mandatory_request_type_to_event(in_msg.Type), in_msg.LineAddress,
                    Dcache_entry, TBEs[in_msg.LineAddress]);
          } else {

            // Check to see if it is in the OTHER L0
            Entry Icache_entry := getICacheEntry(in_msg.LineAddress);
            if (is_valid(Icache_entry)) {
              // The block is in the wrong L0, put the request on the queue to the private L1
              trigger(Event:L0_Replacement, in_msg.LineAddress,
                      Icache_entry, TBEs[in_msg.LineAddress]);
            }

            if (Dcache.cacheAvail(in_msg.LineAddress)) {
              // L1 does't have the line, but we have space for it
              // in the L0 let's see if the L1 has it
              trigger(mandatory_request_type_to_event(in_msg.Type), in_msg.LineAddress,
                      Dcache_entry, TBEs[in_msg.LineAddress]);
            } else {
              // No room in the L1, so we need to make room in the L0
              trigger(Event:L0_Replacement, Dcache.cacheProbe(in_msg.LineAddress),
                      getDCacheEntry(Dcache.cacheProbe(in_msg.LineAddress)),
                      TBEs[Dcache.cacheProbe(in_msg.LineAddress)]);
            }
          }
        }
      }
    }
  }

  // ACTIONS
  action(a_issueGETS, "a", desc="Issue GETS") {
    peek(mandatoryQueue_in, RubyRequest) {
      enqueue(requestNetwork_out, CoherenceMsg, latency=request_latency) {
        out_msg.Addr := address;
        out_msg.Class := CoherenceClass:GETS;
        out_msg.Sender := machineID;
        out_msg.Destination := createMachineID(MachineType:L1Cache, version);
        DPRINTF(RubySlicc, "address: %s, destination: %s\n",
                address, out_msg.Destination);
        out_msg.MessageSize := MessageSizeType:Control;
        out_msg.AccessMode := in_msg.AccessMode;
      }
    }
  }

  action(b_issueGETX, "b", desc="Issue GETX") {
    peek(mandatoryQueue_in, RubyRequest) {
      enqueue(requestNetwork_out, CoherenceMsg, latency=request_latency) {
        out_msg.Addr := address;
        out_msg.Class := CoherenceClass:GETX;
        out_msg.Sender := machineID;
        DPRINTF(RubySlicc, "%s\n", machineID);
        out_msg.Destination := createMachineID(MachineType:L1Cache, version);

        DPRINTF(RubySlicc, "address: %s, destination: %s\n",
                address, out_msg.Destination);
        out_msg.MessageSize := MessageSizeType:Control;
        out_msg.AccessMode := in_msg.AccessMode;
      }
    }
  }

  action(c_issueUPGRADE, "c", desc="Issue GETX") {
    peek(mandatoryQueue_in, RubyRequest) {
      enqueue(requestNetwork_out, CoherenceMsg, latency= request_latency) {
        out_msg.Addr := address;
        out_msg.Class := CoherenceClass:UPGRADE;
        out_msg.Sender := machineID;
        out_msg.Destination := createMachineID(MachineType:L1Cache, version);

        DPRINTF(RubySlicc, "address: %s, destination: %s\n",
                address, out_msg.Destination);
        out_msg.MessageSize := MessageSizeType:Control;
        out_msg.AccessMode := in_msg.AccessMode;
      }
    }
  }

  action(f_sendDataToL1, "f", desc="send data to the L2 cache") {
    enqueue(requestNetwork_out, CoherenceMsg, latency=response_latency) {
      assert(is_valid(cache_entry));
      out_msg.Addr := address;
      out_msg.Class := CoherenceClass:INV_DATA;
      out_msg.DataBlk := cache_entry.DataBlk;
      out_msg.Dirty := cache_entry.Dirty;
      out_msg.Sender := machineID;
      out_msg.Destination := createMachineID(MachineType:L1Cache, version);
      out_msg.MessageSize := MessageSizeType:Writeback_Data;
    }
  }

  action(fi_sendInvAck, "fi", desc="send data to the L2 cache") {
    peek(messgeBuffer_in, CoherenceMsg) {
      enqueue(requestNetwork_out, CoherenceMsg, latency=response_latency) {
        out_msg.Addr := address;
        out_msg.Class := CoherenceClass:INV_ACK;
        out_msg.Sender := machineID;
        out_msg.Destination := createMachineID(MachineType:L1Cache, version);
        out_msg.MessageSize := MessageSizeType:Response_Control;
      }
    }
  }

  action(forward_eviction_to_cpu, "\cc", desc="sends eviction information to the processor") {
    if (send_evictions) {
      DPRINTF(RubySlicc, "Sending invalidation for %s to the CPU\n", address);
      sequencer.evictionCallback(address);
    }
  }

  action(g_issuePUTX, "g", desc="send data to the L2 cache") {
    enqueue(requestNetwork_out, CoherenceMsg, latency=response_latency) {
      assert(is_valid(cache_entry));
      out_msg.Addr := address;
      out_msg.Class := CoherenceClass:PUTX;
      out_msg.DataBlk := cache_entry.DataBlk;
      out_msg.Dirty := cache_entry.Dirty;
      out_msg.Sender:= machineID;
      out_msg.Destination := createMachineID(MachineType:L1Cache, version);

      if (cache_entry.Dirty) {
        out_msg.MessageSize := MessageSizeType:Writeback_Data;
      } else {
        out_msg.MessageSize := MessageSizeType:Writeback_Control;
      }
    }
  }

  action(h_load_hit, "h", desc="If not prefetch, notify sequencer the load completed.") {
    assert(is_valid(cache_entry));
    DPRINTF(RubySlicc, "%s\n", cache_entry.DataBlk);
    sequencer.readCallback(address, cache_entry.DataBlk);
  }

  action(hh_store_hit, "\h", desc="If not prefetch, notify sequencer that store completed.") {
    assert(is_valid(cache_entry));
    DPRINTF(RubySlicc, "%s\n", cache_entry.DataBlk);
    sequencer.writeCallback(address, cache_entry.DataBlk);
    cache_entry.Dirty := true;
  }

  action(i_allocateTBE, "i", desc="Allocate TBE (number of invalidates=0)") {
    check_allocate(TBEs);
    assert(is_valid(cache_entry));
    TBEs.allocate(address);
    set_tbe(TBEs[address]);
    tbe.Dirty := cache_entry.Dirty;
    tbe.DataBlk := cache_entry.DataBlk;
  }

  action(k_popMandatoryQueue, "k", desc="Pop mandatory queue.") {
    mandatoryQueue_in.dequeue();
  }

  action(l_popRequestQueue, "l",
         desc="Pop incoming request queue and profile the delay within this virtual network") {
    profileMsgDelay(2, messgeBuffer_in.dequeue_getDelayCycles());
  }

  action(o_popIncomingResponseQueue, "o",
         desc="Pop Incoming Response queue and profile the delay within this virtual network") {
    profileMsgDelay(1, messgeBuffer_in.dequeue_getDelayCycles());
  }

  action(s_deallocateTBE, "s", desc="Deallocate TBE") {
    TBEs.deallocate(address);
    unset_tbe();
  }

  action(u_writeDataToCache, "u", desc="Write data to cache") {
    peek(messgeBuffer_in, CoherenceMsg) {
      assert(is_valid(cache_entry));
      cache_entry.DataBlk := in_msg.DataBlk;
      cache_entry.Dirty := in_msg.Dirty;
    }
  }

  action(ff_deallocateCacheBlock, "\f",
         desc="Deallocate L1 cache block.") {
    if (Dcache.isTagPresent(address)) {
      Dcache.deallocate(address);
    } else {
      Icache.deallocate(address);
    }
    unset_cache_entry();
  }

  action(oo_allocateDCacheBlock, "\o", desc="Set L1 D-cache tag equal to tag of block B.") {
    if (is_invalid(cache_entry)) {
      set_cache_entry(Dcache.allocate(address, new Entry));
    }
  }

  action(pp_allocateICacheBlock, "\p", desc="Set L1 I-cache tag equal to tag of block B.") {
    if (is_invalid(cache_entry)) {
      set_cache_entry(Icache.allocate(address, new Entry));
    }
  }

  action(z_stallAndWaitMandatoryQueue, "\z", desc="recycle cpu request queue") {
    stall_and_wait(mandatoryQueue_in, address);
  }

  action(kd_wakeUpDependents, "kd", desc="wake-up dependents") {
    wakeUpAllBuffers(address);
  }

  action(uu_profileInstMiss, "\ui", desc="Profile the demand miss") {
        ++Icache.demand_misses;
  }

  action(uu_profileInstHit, "\uih", desc="Profile the demand miss") {
        ++Icache.demand_hits;
  }

  action(uu_profileDataMiss, "\ud", desc="Profile the demand miss") {
        ++Dcache.demand_misses;
  }

  action(uu_profileDataHit, "\udh", desc="Profile the demand miss") {
        ++Dcache.demand_hits;
  }

  //*****************************************************
  // TRANSITIONS
  //*****************************************************

  // Transitions for Load/Store/Replacement/WriteBack from transient states
  transition({IS, IM, SM}, {Load, Ifetch, Store, L0_Replacement}) {
    z_stallAndWaitMandatoryQueue;
  }

  // Transitions from Idle
  transition({NP,I}, L0_Replacement) {
    ff_deallocateCacheBlock;
  }

  transition({NP,I}, Load, IS) {
    oo_allocateDCacheBlock;
    i_allocateTBE;
    a_issueGETS;
    uu_profileDataMiss;
    k_popMandatoryQueue;
  }

  transition({NP,I}, Ifetch, IS) {
    pp_allocateICacheBlock;
    i_allocateTBE;
    a_issueGETS;
    uu_profileInstMiss;
    k_popMandatoryQueue;
  }

  transition({NP,I}, Store, IM) {
    oo_allocateDCacheBlock;
    i_allocateTBE;
    b_issueGETX;
    uu_profileDataMiss;
    k_popMandatoryQueue;
  }

  transition({NP, I, IS, IM}, Inv) {
    fi_sendInvAck;
    l_popRequestQueue;
  }

  transition(SM, Inv, IM) {
    fi_sendInvAck;
    l_popRequestQueue;
  }

  // Transitions from Shared
  transition({S,E,M}, Load) {
    h_load_hit;
    uu_profileDataHit;
    k_popMandatoryQueue;
  }

  transition({S,E,M}, Ifetch) {
    h_load_hit;
    uu_profileInstHit;
    k_popMandatoryQueue;
  }

  transition(S, Store, SM) {
    i_allocateTBE;
    c_issueUPGRADE;
    uu_profileDataMiss;
    k_popMandatoryQueue;
  }

  transition(S, L0_Replacement, I) {
    forward_eviction_to_cpu;
    ff_deallocateCacheBlock;
  }

  transition(S, Inv, I) {
    forward_eviction_to_cpu;
    fi_sendInvAck;
    ff_deallocateCacheBlock;
    l_popRequestQueue;
  }

  // Transitions from Exclusive
  transition({E,M}, Store, M) {
    hh_store_hit;
    uu_profileDataHit;
    k_popMandatoryQueue;
  }

  transition(E, L0_Replacement, I) {
    forward_eviction_to_cpu;
    g_issuePUTX;
    ff_deallocateCacheBlock;
  }

  transition(E, {Inv, Fwd_GETX}, I) {
    // don't send data
    forward_eviction_to_cpu;
    fi_sendInvAck;
    ff_deallocateCacheBlock;
    l_popRequestQueue;
  }

  transition(E, {Fwd_GETS, Fwd_GET_INSTR}, S) {
    f_sendDataToL1;
    l_popRequestQueue;
  }

  // Transitions from Modified
  transition(M, L0_Replacement, I) {
    forward_eviction_to_cpu;
    g_issuePUTX;
    ff_deallocateCacheBlock;
  }

  transition(M, {Inv, Fwd_GETX}, I) {
    forward_eviction_to_cpu;
    f_sendDataToL1;
    ff_deallocateCacheBlock;
    l_popRequestQueue;
  }

  transition(M, {Fwd_GETS, Fwd_GET_INSTR}, S) {
    f_sendDataToL1;
    l_popRequestQueue;
  }

  transition(IS, Data, S) {
    u_writeDataToCache;
    h_load_hit;
    s_deallocateTBE;
    o_popIncomingResponseQueue;
    kd_wakeUpDependents;
  }

  transition(IS, Data_Exclusive, E) {
    u_writeDataToCache;
    h_load_hit;
    s_deallocateTBE;
    o_popIncomingResponseQueue;
    kd_wakeUpDependents;
  }

  transition(IS, Data_Stale, I) {
    u_writeDataToCache;
    h_load_hit;
    s_deallocateTBE;
    o_popIncomingResponseQueue;
    kd_wakeUpDependents;
  }

  transition({IM,SM}, Data_Exclusive, M) {
    u_writeDataToCache;
    hh_store_hit;
    s_deallocateTBE;
    o_popIncomingResponseQueue;
    kd_wakeUpDependents;
  }
}